Life Science Journal 2013;10(1)
Control the post harvest infection by Aspergillus spp. to Taify table grape using grape epiphytic bacteria
Abd El-Raheem Ramadan El-Shanshoury1, 3*, Saleh Ali Bazaid2, Yasser El-Halmouch1, 4 and Mohamed Waheed Eldin Ghafar1, 5
1. Department of Biotechnology, Faculty of Science, Taif University, P.O. Box 888,Taif 21974, Kingdom of Saudi Arabia
2.Department of Biology, Faculty of Science, Taif University, P.O. Box 888, Taif 21974, Kingdom of Saudi Arabia
3. Department of Botany, Bacteriology Unit, Faculty of Science, Tanta University, Tanta 31527, Egypt
4.Department of Botany, Faculty of Science, Damanhour University, Damanhour 22511, Egypt
5. Department of Zoonoses, College of Veterinary Medicine, Cairo University, Cairo, Egypt
Abstract:This study aimed to control the common fungi causing post-harvest black rot of Taify table grape (Vitis vinefra L.) and to induce resistance against black Aspergilli. Six fungal genera belonging to Aspergillus, Penicillium, Trichoderma, Mucor, Rhizopus and Botrytis were isolated from contaminated grape samples, with different frequencies. The predominant fungal species belonged to the genus Aspergillus and the isolation frequency ranged between 2.40-18.66%. The most predominant black Aspergilli were identified to the molecular level based on 18S- rRNA, ITS1 and 5.8S-rRNA gene sequence as A. niger BAVSH1, A. parasiticus BAVSH4 and A. tubingensis BAVSH5. Forty one bacterial isolates were obtained from soil, meswak and the surface of grape fruits, and screened for antagonistic activity. In vitro dual microbial culture showed variable % inhibition of fungal growth values. Out of the active antagonistic bacteria, five epiphytic from grape fruits and one from meswak, being the most antagonistic were identified to the molecular level based on 16S rRNA gene sequence as Pseudomonas aeruginosa EBMSH1, P. aeruginosa EBVSH13, P. aeruginosa EBVSH14, P. aeruginosa EBVHSH17, Bacillus vallismortis EBHVSH28 and B. amyloliquefaciens EBHVSH29. The ability of living cells or crude cell extracts of the best three latter antagonistic bacteria to induce the resistance in pre-wounded and intact- flooded grape fruits against black Aspergillus rot disease progress were demonstrated. Higher reduction or complete absence of disease incidence% and lesion diameter were obtainedin intact, pre-wounded and living bacteria treated fruits than untreated control. This was clearer in flooding treatmentswith crude cell extractand living bacteria, compared to some of thewounded and induced by living bacteria and no treated control.
[El-ShanshouryAR, BazaidSA, El-HalmouchY,Ghafar M. Control the post harvest infection by Aspergillus spp. to Taify table grape using grape epiphytic bacteria.Life Sci J2013; 10(1):1821-1836] (ISSN: 1097-8135).
Keywords: Aspergillus spp.;Bacillus spp.;biological control;epiphytic bacteria; Pseudomonas sp.; post harvest
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Life Science Journal 2013;10(1)
1. Introduction
Grape (Vitis vinifera L.) represents 8.5 % of fruit crops planted area in Saudi Arabia. The most cultivated regions are Medinah and Tabouk which produce about 33.4 and 14.9 % of the total grape production, respectively (ARDA 2006). Taif area is also famous of fruits and grape is considered as one of the important summer fruits in this area. Significant portion of the grape is lost due to diseases caused by fungi and / or bacteria, physical injuries, over ripening and non-disease disorders (Boyette et al., 1992). If efficient steps are not taken to prevent the spread of these organisms and their toxins (Abrunhosa et al., 2001;Cabañes et al., 2002; Sageet al., 2002;Battilaniet al., 2003; Medina et al., 2005 and Lui et al., 2010), it can infect all the products that are subsequently processed and pose a public health hazard (International programme on chemical safety, 1990; MajerusandOtteneder1996;Heenan et al., 1998;Codex Alimentarius Commission, 1999; Abrunhosa etal., 2002 and Bayman et al., 2002). The contamination of grapes with fungi attracted the attention of some investigators (Sageet al., 2002;Battilaniet al., 2003; Medina et al., 2005;Guzevet al., 2008; Allam et al., 2008 and Al-Qurashi, 2010).
Formation of fruit pathogens resistance to fungicides, contamination with chemical and detrimental effects of chemical control encouraged scientists to search for alternative control methods based on biological control of plant pathogens by means of non-pathogenic bacteria and fungi. However, considerable success has been achieved by utilizing antagonistic microorganisms for controlling plant diseases, post harvest diseases and mycotoxins (Pusey and Wilson, 1984;Spotts and Cervantes, 1986; Ferreira, 1990; El-Abyad et al., 1993,1996;El-Shanshoury, 1994;El-Ghaouth and Wilson, 1995,1998; El-Ghaouth et al., 2003;Gonzalez et al., 2005;Visconti et al., 2008; Abrunhosa et al., 2010; Lui et al., 2010 and Somma et al., 2012). In this context, the epiphytic and endophytic microorganisms existing in the fruits were the object of studies conducted by many investigators (Wisniewski and Wilson, 1992; Sobiczewski and Bryk, 1995; He et al., 2003; Han et al., 2004; Bleve et al., 2006; El-Tarabily, 2006; Slavov, 2006; Chanchaichaovivata et al., 2007;Haıssam, 2011andParani et al., 2011). Recently, Somma et al. (2012) reviewed the prevention and control of black Aspergilli and Ponsone et al. (2011) demonstrated the efficacy of two yeast strains of Kluyveromyces thermotolerans for reducing the growth rate of ochratoxigenic fungi (from 11 to 82.5%), in the field.
The production of grapevine metabolites is highly conditioned by environment or pathogen attacks (Ali et al., 2010). Several abiotic and biotic agents have been reported to induce plant resistance to pathogens (Sticher et al., 1997; Sholberg and Conway, 2004; Nandeeshkumar et al., 2008; Yu et al., 2008 andPoiatti et al., 2009) in order to mobilize appropriate cellular defense responses before or upon pathogen attack (Sticher et al., 1997) triggered by non-pathogenic bacteria (Sholberg and Conway, 2004; Compant et al., 2005; Bakker et al., 2007; Magnin-Robert et al., 2007; Nandeeshkumar et al., 2008; Trotel-Aziz et al., 2008; Yu et al., 2008; Poiatti et al., 2009; Verhagen et al., 2010 andBaz et al., 2012).
The objectives of this study aimed to record the post harvest mycobiota of Taify table grape, to identify those causing black rot in different Taify farms to monitor their growth. This is in order to search for better management by using specific and preventive treatments. The potential of three biocontrol bacteria Pseudomonas aeruginosa EBVHSH17, Bacillus vallismortis EBHVSH28 and B. amyloliquefaciens EBHVSH29 to control Aspergillus black rot on Taify table grape and to enhance the resistance to subsequent infection with A. niger BAVSH1, A. parasiticus BAVSH4 and A. tubingensis BAVSH5 were explored.
2. Material and Methods
Samples
In the present study, a total of 30 Taify table grape samples (Vitis vinifera L.) were collected from six private farms at Taif city. Samples were harvested in July during the grape harvest. Grape bunches (each about 1 kg) were taken and placed in previously sterilized cardboard boxes, which were kept at 4°C until analysis.
Isolation and identification of fungi
Fungi were isolated from the infected grape fruits. Five weighted fruits were cut into small pieces and vigorously shaken in 100 ml of phosphate buffer (pH 6.5) for 20 min. The number of fungi was determined using serial dilution plate method on Sabouraud's agar medium containing the following ingredients 10 g l_1 meat peptone, 40 g l_1 dextrose and 15 g l_1 agar. Rose pengal (0.05 g l_1) was added to the medium to suppress any bacterial growth. Colonies from fruits appeared on solid medium were chosen on the basis of their different visual characteristics. After 48-72 h of incubation at 280C, the number of CFU of filamentous fungi per gram of fruit was evaluated. The morphologically differing colonies of fungi were retransferred onto new plates for purification. Fungal colonies with different morphologies were maintained on Sabouraud's agar slants and stored at 4-8ºC for further studies.
Taxonomic identification of all fungal isolates was achieved through macroscopic and microscopic observation with the aid of guidelines published for each genus or general guidelines (Barnett and Hunter, 1972;Pitt and Ailsa, 1985 andTuite and Cantone, 1990). Molecular identification was also applied on the selected black Aspergillii on the basis of determination of restriction patterns of PCR-amplified rRNA gene products. Fungal DNA was isolated according to the method described by Lee and Taylor (1990). The ITS1-5.8S-rRNA gene-ITS2 region was amplified by PCR. Two oligonucleotide fungal primers (ITS1 and ITS2) described by White et al. (1990) were used for amplification. Amplified products were digested overnight at 37°C with restriction endonuclease RsaI (Boehringer Mannheim). To perform DNA sequencing, PCR products were cleaned with the Gene Clean II Purification kit (Bio 101, La Jolla, Calif.). Then, PCR products were sequenced using the Taq DyeDeoxy terminator cycle sequencing kit (Applied Biosystems, Falmer, Brighton, United Kingdom) and an Applied Biosystems automated DNA sequencer (model 3130xI) according to the manufacturer's instructions. The universal primers for ITS1 and ITS2 were used to obtain the sequence of both strands. The National Center for Biotechnology Information (NCBI) Nucleotide Database was used to compare nucleotide sequences and aligned using CLUSTAL W (1.81) Multiple Sequence Alignment generating phylogenetic tree. The sequences of fungal isolates reported here were deposited in the DDBJ/EMBL/GenBank nucleotide sequence database under the accession numbers: AB761050 (Aspergillus niger BAVSH1), AB761051 (Aspergillus parasiticus BAVSH4), AB761052 (Aspergillus tubingensis BAVSH5) and AB761053 (Rhizopus oryzae BRVSH7).
Isolation of antagonistic bacteria
Naturally occurring epiphytic bacteria were isolated from the surface of Taify table grape at harvest and periods of storage according to the methods of Assis and Mariano (1999) and Yrjälä et al. (2010), with some modifications. Five grapes were picked from bunches, rinsed in 100 ml of sterile distilled water in Erlenmeyer flask, mixed with 1 g sterilized glass beads (0.2 cm diameter) and shaken at 150 rpm and at 28oC for 20 minutes. Another five grapes were picked up for isolation of rare epiphytic bacteria, rinsed in 100 ml of sterile distilled water in Erlenmeyer flask, boiled for 20 minutes, mixed with 1 g sterilized glass beads (0.2 cm diameter) and shaken at 150 rpm and at 28oC for 20 minutes. One gram of soil was also dispensed in 100 ml sterile distilled water and shaken for 20 minutes. The rinsing waters resulted from the grape and soils were subjected to decimal dilutions under sterile conditions. An aliquot of 1 ml of each dilution was placed in plates containing nutrient yeast dextrose agar (NYDA) medium (containing 8 g of nutrient broth, 5 g of yeast extract, 10 g of glucose, and 20 g of agar in 1 liter of distilled water). Colonies appeared were chosen on the basis of their different visual characteristics. After 24-48h of incubation, the morphologically differing colonies of the isolates were re-streaked on the corresponding medium to obtain pure cultures. These pure cultures were maintained on slants containing the corresponding medium and stored at 4oC until further study.
Identification of antagonistic bacteria
Morphological, physiological and biochemical confirmatory tests in Butler (1986) were followed for characterization of the antagonistic bacteria. The results on morphological and physiological characteristics were used, in addition to 16S rRNA sequencing technique for the confirmation of bacteria identification.
Molecular characterization of bacterial isolates
Genomic DNA was extracted from bacterial isolates as described by Sambrook andRussell(2001) using GenEluteTm bacterial genomic DNA kit, Sigma Aldrich. The genomic DNA was resuspended in 50 ml of TE buffer (10 mM Tris, 1mM EDETA), pH 8.0 and stored at -20oC until used in PCR amplification. The 16S rRNA gene about 1.5 Kb long was PCR amplified using set of the universal primers; forward primer, 5'-AGAGTTTGATCCTGGTCAGAACGCT-3' and reverse primer, 5'TACGGCTACCTTGTTACGACTTCACCCC-3' (Yanagi and Yamasato, 1993), 27F (5′AGAGTTTGATCMTGGCTCAG-3′) and 1525R(5′AAGGAGGTGWTCCARCC-3′) (11, Lane) and forward: AGA GTT TGA TCC TGGCTC AG; reverse: ACG GCT ACC TTG TTA CGA CTT(Weisburg et al., 1991). The PCR reactions were carried out according to the method described by Chouari et al. (2005). The PCR products of 16S rRNA gene were purified using 3130XI genetic analysis (Applied Biosystems).
DNA sequencing and phylogenetic tree
The 1.5 Kb-PCR products of 16S rRNA genes were used for DNA sequencing. Sequence analysis of the DNA fragments was performed. The PCR products were sequenced using the Taq DyeDeoxy terminator cycle sequencing kit (Applied Biosystems, Falmer, Brighton, United Kingdom) and an Applied Biosystems automated DNA sequencer (model 3130xI) according to the manufacturer's instructions. Selected sequences of other microorganisms with greatest similarity to the 16S rRNA sequences of bacterial isolates were extracted from the nucleotide sequence databases in The National Center for Biotechnology Information (NCBI) Nucleotide Database and aligned using CLUSTAL W (1.81) Multiple Sequence Alignment generating phylogenetic tree. The 16S rRNA sequences of bacterial isolates reported here were deposited in the DDBJ/EMBL/GenBank nucleotide sequence database under the accession numbers: AB758242 (Pseudomonas aeruginosa EBMSH1), AB760555 (Pseudomonas aeruginosa EBVSH13), AB761046 (Pseudomonas aeruginosa EBVSH14), AB761047 (Pseudomonas aeruginosa EBVHVSH17), AB761048 (Bacillus vallismortis EBHVSH28)and AB761049 (Bacillus amyloliquefaciens EBHVSH29).
In Vitro antagonism tests
The forty one isolated bacterial strains were tested In Vitro, using the dual culture method (modified procedure of Fuhrmann (1994). Plates (90 mm) diameters containing Sabouraud,s agar medium were inoculated with bacteria, 48 hr prior to the fungal inoculation. Each isolate was placed on a Petri dish making uniformly crossed streaks equidistantly near the periphery of each plate. Agar plugs (5-mm diameter) were taken from a growing edge of a 5-day-old test fungal colony and transferred to the centre of the test agar plate surface (3 replicates). Cultures were incubated at 28oC and when growing edges of control fungi (without any antagonistic inoculums) were at the edge of the plates, the diameters of the test fungal colonies toward each bacterium were measured. Antagonism against the fungi was evaluated using percentage inhibition values (I).
I = radius of control fungus - radius of test fungus x100/ radius of control fungus
Antagonistic activity of the highly antagonistic strains was repeated on plates with a single individual antagonistic streak and checked after three and 10 days of co-cultivation. Each treatment (each isolate) was done in triplicate and each experiment was conducted three times. The isolates that showed the highest inhibition or completely inhibited fungal growth called antagonistic isolates were used for further studies.
Nature of the interactions between antagonists and fungi
The morphology of test fungal mycelia adjacent to the bacteria growth was examined under compound microscope (400x) for abnormal growth patterns and to ascertain whether or not there were direct contacts between bacterial and fungal colonies. The response of spores or mycelia plugs of the three susceptible fungi to form viable colonies was evaluated on agar blocks (5mmx5mm) cut from clear zones formed in dual culture plates.
Fruit material, antagonists and fungal pathogens
Taify table grape fruits (Vitis vinifera L.) were harvested at maturity and those having uniformity in size and ripeness, and lack of any apparent injuries or infection were selected. Fruit samples were surface-disinfected with sodium hypochlorite at 0.1% (v/v) for 1 min, rinsed with sterile tap water for three times, and allowed to air dry at room temperature (20oC).
The best antagonistic bacteria P. aeruginosa EBVHSH17, B. vallismortis EBHVSH28 and B. amyloliquefaciens EBHVSH29 that were originally isolated from the surface of grape fruit as mentioned before, streaked on nutrient yeast dextrose agar (NYDA) and incubated at 28°C for 48 hr. The bacterial cells were cultured in nutrient yeast dextrose broth (NYDB) and incubated for 24 h at 28oC on a rotatory shaker at 200 rpm. The cells were harvested by centrifuging at 4,000 rpm for 20 min and washed twice with sterile distilled water. The concentrations of inoculants of biocontrol agents were adjusted to 108 cells/ml colony forming unit (CFU) by dilution plating onto NYDA.
The pathogens A. niger BAVSH1, A. parasiticus BAVSH4 and A. tubingensis BAVSH5 that originally isolated from grape fruits and showing typical black rot were cultivated on Sabouraud,s agar medium at 28oC in the dark for seven days. Spore suspensions were prepared by gently rubbing the culture surface of sporulating cultures of the test fungi by glass rod after adding adequate amount of sterile distilled water contained 0.1% Tween 80. The spore concentration was adjusted to 104 spores/ml CFU by dilution plating on Sabouraud,s agar.
In vivo biocontrol of black Aspergilli rot
For postharvest disease assays, the surface-disinfected grape fruits were wounded in the middle with a sterile cylindrical tool (approximately 2 mm diameter and 3 mm deep) and the cut tissue was removed. Into each wound, 30 µl of sterile water or bacterial living cells suspension of the antagonistic bacteria P. aeruginosa EBVHSH17, B. vallismortis EBHVSH28 and B. amyloliquefaciens EBHVSH29, in sterile distilled water, adjusted at 1×108 cells/ml were pipetted and inoculated. Intact grape fruits were flooded and shaked for 20 min at 120 rpm with either the living bacterial cell suspension at 1×108 cells/ml or with crude cell extracts from freeze dried and thawed bacterial cell suspension at 1×108 cells/ml. After the suspensions were absorbed, the fruits were wounded after 72 hr. Then after, the fruits were challenged each with 30 µl containing 1×104 spores/ml CFU with the pathogens A. niger BAVSH1, A. parasiticus BAVSH4 or A. tubingensis BAVSH5. Wounds treated with sterile distilled water and with fungal spore suspension served as the inoculated positive disease controls. In each experiment, wounds treated with either sterile distilled water, or antagonistic bacteria suspension, without pathogen inoculation was used as negative controls. For all experiments, negative controls did not show disease symptoms. After air drying, the treated grapes were stored at 20 and 5oC in pre-disinfected, covered plastic containers to maintain a high relative humidity. The number of infected fruits and their lesion diameters were examined daily and recorded every fourth day after fungal challenge, started after four and ten days for those incubated at 20oC and 5oC, respectively.
3. Results
Fungal contamination of grapes
Table 1 shows the contamination levels of the Taify table grape, collected from six different private farms at Taif by the fungal genera and the total counts. Umm El-Erad number 3 was the most contaminated farm with 3.25×102 CFU/ g. Mathnaa farm number 1 showed the lowest level of fungal contamination 0.79×102 CFU/g, followed with Umm El-Erad number 4 that contaminated with 1.58×102 CFU/ g. The remaining grape farms showed nearly similar contamination levels which were 2.56×102, 2.56×102 and 2.30×102, respectively. From the fungal infected samples, 11 species with variable frequencies from the grape samples were purified and identified. They were mainly assigned to six genera namely Aspergillus, Penicillium, Mucor, Rhizopus, Trichoderma and Botrytis. Penicillium was isolated from four farms but not found in the remaining farms. Aspergillus fumigatus, Mucor and Botrytis spp. were isolated from three farms but not found in the remaining farms, while Rhizopous sp. was isolated from only two farms and not found in the remaining farms. Occurrence of Penicillium, Mucor, Rhizopus and Botrytis was very low.